p53 and DNA damage-inducible expression of the xeroderma pigmentosum group C gene

Impaired processing of DNA photoproducts and ultraviolet hypermutability with loss of p16INK4a or p19ARF

Reduced DNA repair has been linked to an increased risk of cutaneous malignant melanoma, but insights into the molecular mechanisms of that link are scarce. The INK4a/ARF (CDKN2a) locus, which codes for the p16(INK4a) and p19ARF proteins, is often mutated in sporadic and familial malignant melanoma, but it has not been directly associated with reduced DNA repair. We transfected unirradiated mouse fibroblast cells with UV-treated DNA to measure DNA repair in normal, p16INK4a mutant, p19ARF mutant, or double mutant mouse host cells. Loss of either p16(INK4a) or p19ARF reduced the ability of the cells to process UV-induced DNA damage, independent of cell cycle effects incurred by the loss. These results may further explain why INK4a/ARF mutations predispose to malignant melanoma, a UV-induced tumor.

Expression of hepatitis B virus X oncoprotein inhibits transcription-coupled nucleotide excision repair in human cells

The hepatitis B virus X protein (HBx) is implicated in liver cancer development, and this presumably involves its ability to bind and functionally inactivate the p53 tumour suppressor. For example expression of HBx in cultured cells has been shown to inhibit global nucleotide excision repair, a p53-dependent subpathway of nucleotide excision repair (NER) which eliminates helix-distorting DNA adducts, e.g., UV-induced cyclobutane pyrimidine dimers (CPDs), from the genome overall. However it remains undetermined whether HBx also interferes with transcription-coupled NER (TCNER), another NER subpathway which removes DNA adducts uniquely from the transcribed strand (TS) of active genes. To address this, we employed the model human lymphoblastoid strain TK6 and its isogenic p53-null counterpart NH32, in conjunction with derivatives of these strains constitutively expressing HBx (TK6-HBx and NH32-HBx). Relative to TK6, following exposure to either UVB (290-320 nm) or UVC (254 nm), TK6-HBx, NH32 and NH32-HBx manifested significantly reduced apoptotic capacity to varying degrees, although no striking differences in clonogenic survival between the four strains were observed. As previously documented in our laboratory [Proc. Natl. Acad. Sci. 100 (2003) 7219-7224], ligation-mediated PCR analysis revealed NH32 to be deficient compared with TK6 in CPD removal along the TS strand of the chromosomal c-jun locus following UVB exposure, but to be proficient in this respect following UVC exposure, i.e., the requirement for p53 in TCNER exhibits wavelength dependence in human cells. Remarkably however, in contrast to the situation for NH32, TK6-HBx and NH32-HBx manifested defective repair along the TS of c-jun after irradiation with either UVB or UVC. The data demonstrate that HBx expression can reduce the efficiency of TCNER in addition to GNER in human cells via p53-independent as well as p53-dependent pathways.

Cells synchronized in S phase show increased rate of repair of UV damaged plasmids

The capacity for nucleotide excision repair of cells synchronized in S phase and unsynchronized cells was compared by the host cell reactivation assay and the cell-free repair system. HeLa cells were transfected with in vitro damaged by UV irradiation pEGFP and the repair capacity was determined by the number of fluorescent cells. In the cell-free repair system, the repair capacity of protein extracts isolated from K562 cells was determined by measuring the transformation efficiency of UV irradiated pBlueScript incubated in the extracts. In both cases, the repair capacity of the cells synchronized in S phase cells was 30-50% higher than the repair capacity of unsynchronized cells.

p53 Heterozygosity Results in an Increased 2-Acetylaminofluorene-Induced Urinary Bladder but not Liver Tumor Response in DNA Repair-Deficient Xpa Mice

Both nucleotide excision repair (NER) and the p53 tumor suppressor protein play crucial roles in the prevention of cells becoming cancerous. This is clearly demonstrated by the fact that NER-deficient xeroderma pigmentosum patients and Li-Fraumeni patients who carry a germ-line p53 mutation are highly tumor prone. The NER-deficient Xpa and the p53(+/-) mouse models clearly mimic their human counterparts, because they are both tumor prone as well. The aim of the study presented here was to analyze the relative contribution of these two pathways in tumor suppression and to analyze a possible link between NER and p53 activation in vivo. For this, we exposed Xpa, p53(+/-), and Xpa/p53(+/-) mice to 2-acetylaminofluorene (2-AAF). We show that 2-AAF-induced urinary bladder tumor suppression is dependent on p53 status, because p53(+/-) mice were highly tumor prone. Xpa/p53(+/-) mice were even more tumor prone, whereas no increased tumor response was found in Xpa mice. Short-term assays revealed a decreased apoptotic response in Xpa/p53(+/-) mice, pointing in vivo toward a link between NER and p53-mediated apoptosis. In contrast, liver tumor response was primarily dependent on appropriate DNA repair, because Xpa-deficient mice were liver tumor prone. p53 heterozygosity had no influence on liver tumor incidences, in line with the results obtained from the short-term 2-AAF studies revealing no altered cellular response in p53(+/-) or Xpa/p53(+/-) mice. Interestingly, however, mice completely deficient in both NER and p53 (Xpa/p53(-/-) mice) showed a dramatic increase of hepatocellular proliferation accompanied by lacZ reporter gene mutations.

UV-induced de novo protein synthesis enhances nucleotide excision repair efficiency in a transcription-dependent manner in S. cerevisiae

DNA damage results in the up-regulation of several genes involved in different cellular physiological processes, such as the nucleotide excision repair (NER) mechanism that copes with a broad range of DNA alterations, including the carcinogenic ultraviolet (UV) light-induced pyrimidine dimers (PDs). There are two NER sub-pathways: transcription coupled repair (TCR) that is specific for the transcribed strands (TS) of active genes and global genomic repair (GGR) that repairs non-transcribed DNA sequences (NTD) and the non-transcribed strands (NTS) of expressed genes. To elucidate the role of UV-dependent de novo protein synthesis in nucleotide excision repair in the budding yeast, we investigated the effect of the protein synthesis inhibitor, cycloheximide, on the removal of PDs. Log phase as well as G(1)-synchronized cells were treated with the drug shortly before UV irradiation and immediately thereafter, and the repair of damaged DNA was assessed with the high resolution primer extension technique. The results show that in both cellular conditions, the inhibition of UV-dependent de novo protein synthesis by cycloheximide impairs the excision repair of the transcriptionally active GAL10 and URA3 genes, with a greater effect on the non-transcribed strands. This indicates that UV-mediated de novo protein synthesis is required for efficient nucleotide excision repair, but not for the preferential repair of the TSs. On the other hand, cycloheximide did not affect the repair of either strand of the repressed GAL10 gene or the non-transcribed promoter region of the URA3 gene, showing that UV-induced de novo protein synthesis is not required for PD removal from transcriptionally inactive DNA sequences. Together, these data show that despite the fact that NTD and NTSs are normally repaired by the GGR sub-pathway, their requirement for UV-dependent de novo protein synthesis is different, which may suggest a difference in the processing of UV lesions in these non-transcribed sequences of the genome.

Xeroderma pigmentosum: from genetics to hopes and realities of cutaneous gene therapy

Xeroderma pigmentosum (XP) is a rare genodermatosis transmitted as an autosomal and recessive trait. XP patients are highly photosensitive and prone to develop skin tumours in sun-exposed areas. Biochemical and genetic studies have demonstrated that nucleotide excision repair, the most versatile DNA repair mechanism, is deficient in XP cells, leading to ultraviolet-induced hypermutagenesis and a predisposition of XP patients to cancer. Cloning of XP genes responsible for the disease, together with the poor efficacy of classical pharmacological treatments, have motivated approaches towards cutaneous gene therapy of the XP. The author's group have successfully reconstructed XP skin in vitro from XP keratinocytes and fibroblasts. More recently, the possibility to fully revert the phenotype of XP keratinocytes after retrovirus-mediated transfer of the adequate wild-type XP gene in XP keratinocytes was demonstrated. Reconstruction of genetically corrected XP skin in vitro constitutes a new hope toward cutaneous gene therapy of the XP.

Analysis of vitamin D-regulated gene expression in LNCaP human prostate cancer cells using cDNA microarrays

BACKGROUND

1,25-dihydroxyvitamin D(3) [1,25(OH)2D3] exerts growth inhibitory, pro-differentiating, and pro-apoptotic effects on prostate cells. To better understand the molecular mechanisms underlying these actions, we employed cDNA microarrays to study 1,25(OH)2D3-regulated gene expression in the LNCaP human prostate cancer cells.

METHODS

mRNA isolated from LNCaP cells treated with vehicle or 50 nM 1,25(OH)2D3 for various lengths of time were hybridized to microarrays carrying approximately 23,000 genes. Some of the putative target genes revealed by the microarray analysis were verified by real-time PCR assays.

RESULTS

1,25(OH)2D3 most substantially increased the expression of the insulin-like growth factor binding protein-3 (IGFBP-3) gene. Our analysis also revealed several novel 1,25(OH)2D3-responsive genes. Interestingly, some of the key genes regulated by 1,25(OH)2D3 are also androgen-responsive genes. 1,25(OH)2D3 also down-regulated genes that mediate androgen catabolism.

CONCLUSIONS

The putative 1,25(OH)2D3 target genes appear to be involved in a variety of cellular functions including growth regulation, differentiation, membrane transport, cell-cell and cell-matrix interactions, DNA repair, and inhibition of metastasis. The up-regulation of IGFBP-3 gene has been shown to be crucial in 1,25(OH)2D3-mediated inhibition of LNCaP cell growth. 1,25(OH)2D3 regulation of androgen-responsive genes as well as genes involved in androgen catabolism suggests that there are interactions between 1,25(OH)2D3 and androgen signaling pathways in LNCaP cells. Further studies on the role of these genes and others in mediating the anti-cancer effects of 1,25(OH)2D3 may lead to better approaches to the prevention and treatment of prostate cancer.

The initiative role of XPC protein in cisplatin DNA damaging treatment-mediated cell cycle regulation

XPC is an important DNA damage recognition protein involved in DNA nucleotide excision repair. We have studied the role of the XPC protein in cisplatin treatment-mediated cell cycle regulation. Through the comparison of microarray data obtained from human normal fibroblasts and two individual XPC-defective cell lines, 486 genes were identified as XPC-responsive genes in the cisplatin treatment (with a minimal 1.5-fold change) and 297 of these genes were further mapped to biological pathways and gene ontologies. The cell cycle and cell proliferation-related genes were the most affected genes by the XPC defect in the cisplatin treatment. Many other cellular function genes were also affected by the XPC defect in the treatment. Western blot hybridization results revealed that the XPC defect reduced the p53 responses to the cisplatin treatment. The ability to activate caspase-3 was also attenuated in the XPC cells with the treatment. These results suggest that the XPC protein plays a critical role in initiating the cisplatin DNA damaging treatment-mediated signal transduction process, resulting in activation of the p53 pathway and cell cycle arrest that allow DNA repair and apoptosis to take place. These results reveal an important role of the XPC protein in the cancer prevention.

Differential repair of the two major UV-induced photolesions in trichothiodystrophy fibroblasts

Defects in nucleotide excision repair have been shown to be associated with the photosensitive form of the disorder trichothiodystrophy (TTD). Most repair-deficient TTD patients are mutated in the XPD gene, a subunit of the transcription factor TFIIH. Knowledge of the kinetics and efficiency of repair of the two major UV-induced photolesions in TTD is critical to understand the role of unrepaired lesions in the process of carcinogenesis and explain the absence of enhanced skin cancer incidence in TTD patients contrarily to the xeroderma pigmentosum D patients. In this study, we used different approaches to quantify repair of UV-induced cyclobutane pyrimidine dimers (CPD) and pyrimidine (6-4) pyrimidone photoproducts (6-4PP) at the gene and the genome overall level. In cells of two TTD patients, repair of CPD and 6-4PP was reduced compared with normal human cells, but the reduction was more severe in confluent cells than in exponentially growing cells. Moreover, the impairment of repair was more drastic for CPD than 6-4PP. Most notably, exponentially growing TTD cells displayed complete repair 6-4PP over a broad dose range, albeit at a reduced rate compared with normal cells. Strand-specific analysis of CPD repair in a transcriptional active gene revealed that TTD cells were capable to perform transcription-coupled repair. Taken together, the data suggest that efficient repair of 6-4PP in dividing TTD cells in concert with transcription-coupled repair might account for the absence of increased skin carcinogenesis in TTD patients.

Inhibition of DNA primase and induction of apoptosis by 3,3’-diethyl-9-methylthia-carbocyanine iodide in hepatocellular carcinoma BEL-7402 cells

AIM: To evaluate the effects of 3,3’-diethyl-9-methylthia-carbocyanine iodide (DMTCCI) on DNA primase activity and on apoptosis of human hepatocellular carcinoma BEL-7402 cells.

METHODS: DNA primase assay was used to investigate DNA primase activity. MTT assay was applied to determine cell proliferation. Flow cytometric analysis, transmission electron microscopy, DNA fragmentation assay were performed to detect DMTCCI-induced apoptosis. Expression levels of p53, Bcl-2, Bcl-xL, Bad, Bax, survivin, Caspase-3 and poly (ADP-ribose) polymerase (PARP) were evaluated by immunoblot analysis. Caspase-3 activity was assessed with ApoAlert Caspase-3 colorimetric assay kit.

RESULTS: DMTCCI had inhibitory effects on eukaryotic DNA primase activity with IC₅₀ value of 162.2 nmol/L. It also inhibited proliferation of human hepatocellular carcinoma BEL-7402 cells with IC₅₀ value of 2.09 μmol/L. Furthermore, DMTCCI-induced BEL-7402 cell apoptosis was confirmed by DNA fragmentation (DNA ladders and sub-G1 formation) and transmission electron microscopy (apoptotic bodies formation). During the induction of apoptosis, expression of Bcl-2, Bcl-xL and survivin was decreased, and that of p53, Bad and Bax was increased. Caspase-3 was activated and poly (ADP-ribose) polymerase (PARP) was cleaved in BEL-7402 cells treated with DMTCCI.

CONCLUSION: The present data suggest that DMTCCI has inhibitory effects on eukaryotic DNA primase and can induce apoptosis of BEL-7402 cells. The modulation of expression of p53 and Bcl-2 family proteins, and activation of Caspase-3 might be involved in the induction of apoptosis.

Apoptosis induced by MNNG in human TK6 lymphoblastoid cells is p53 and Fas/CD95/Apo-1 related

Agents inducing O(6)-methylguanine (O(6)MeG) in DNA, such as N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), are not only highly mutagenic and carcinogenic but also cytotoxic because of the induction of apoptosis. In CHO fibroblasts, apoptosis triggered by O(6)MeG requires cell proliferation and MutSalpha-dependent mismatch repair and is related to the induction of DNA double-strand breaks (DSBs). Furthermore, it is mediated by Bcl-2 degradation and does not require p53 for which the cells were mutated [Cancer Res. 60 (2000) 5815]. Here we studied cytotoxicity and apoptosis induced by MNNG in a pair of human lymphoblastoid cells expressing wild-type p53 (TK6) and mutant p53 (WTK1) and show that TK6 cells are more sensitive than WTK1 cells to cell killing (determined by a metabolic assay) and apoptosis. Apoptosis was a late response observed <24h after treatment and was related to accumulation of p53 and upregulation of Fas/CD95/Apo-1 receptor as well as Bax. The data indicate that MNNG induces apoptosis in lymphoblastoid cells by activating the p53-dependent Fas receptor-driven pathway. This is in contrast to CHO fibroblasts in which, in response to O(6)MeG, the mitochondrial damage pathway becomes activated.

Mechanisms of human DNA repair: an update

The human genome, comprising three billion base pairs coding for 30000-40000 genes, is constantly attacked by endogenous reactive metabolites, therapeutic drugs and a plethora of environmental mutagens that impact its integrity. Thus it is obvious that the stability of the genome must be under continuous surveillance. This is accomplished by DNA repair mechanisms, which have evolved to remove or to tolerate pre-cytotoxic, pre-mutagenic and pre-clastogenic DNA lesions in an error-free, or in some cases, error-prone way. Defects in DNA repair give rise to hypersensitivity to DNA-damaging agents, accumulation of mutations in the genome and finally to the development of cancer and various metabolic disorders. The importance of DNA repair is illustrated by DNA repair deficiency and genomic instability syndromes, which are characterised by increased cancer incidence and multiple metabolic alterations. Up to 130 genes have been identified in humans that are associated with DNA repair. This review is aimed at updating our current knowledge of the various repair pathways by providing an overview of DNA-repair genes and the corresponding proteins, participating either directly in DNA repair, or in checkpoint control and signaling of DNA damage.

Cloning and characterization of a novel gene PDRG that is differentially regulated by p53 and ultraviolet radiation

We report the cloning and characterization of a novel p53 and DNA damage-regulated gene (PDRG). The human and mouse PDRG sequences are highly homologous and contain open reading frames of 133 amino acids each with molecular masses of 15.5 and 15.3 kDa, respectively. PDRG codes for a novel protein that does not show similarity to any known protein in the databases. Human PDRG is predominantly expressed in normal testis and exhibits reduced but detectable expression in other organs. GFP-tagged PDRG was predominantly detected as aggregates that appeared to reside in a distinct subcellular compartment. PDRG mRNA was upregulated by ultraviolet radiation (UV) but downregulated by tumor suppressor p53. UV is known to transcriptionally upregulate the expression of certain genes by activating the transcription factor Oct-1, while p53 has been reported to suppress transcription of certain genes by directly binding to a novel head-to-tail response element. Cloning and sequence analysis of PDRG promoter revealed the presence of Oct-1-binding element and a putative head-to-tail-type p53-binding site. Indeed, UV as well as exogenous Oct-1 independently increased PDRG promoter activity, suggesting that UV could mediate PDRG upregulation via Oct-1. Exogenous wild-type p53 was found to downregulate the PDRG promoter activity indicating that wild-type p53 transcriptionally suppresses the expression of PDRG and may mediate its effect via the putative head-to-tail response element. Furthermore, stable expression of exogenous PDRG was found to decrease the clonogenic survival after UV irradiation, which highlights the significance of PDRG in facilitating UV-induced killing.

APE/Ref-1 and the mammalian response to genotoxic stress

Human apurinic/apyrimidinic endonuclease/redox factor-1 (hAPE/Ref-1) is a multifunctional protein involved in the repair of DNA damaged by oxidative or alkylating compounds as well as in the regulation of stress inducible transcription factors such as AP-1, NF-kappaB, HIF-1 and p53. With respect to transcriptional regulation, both redox dependent and independent mechanisms have been described. APE/Ref-1 also acts as a transcriptional repressor. Recent data indicate that APE/Ref-1 negatively regulates the activity of the Ras-related GTPase Rac1. How these different physiological activities of APE/Ref-1 are coordinated is poorly understood. So far, convincing evidence is available that the expression of the APE/Ref-1 gene is inducible by oxidative stress and that overexpressed APE/Ref-1 protein protects cells against the genotoxic and cell killing effects of reactive oxygen species (ROS), whereas down-regulation sensitizes cells. Therefore, APE/Ref-1 can be considered to be part of an adaptive cellular response mechanism to oxidative genotoxic stress. The physiological relevance of increase of either the repair or redox activity of APE/Ref-1 for this adaptive response is unclear. Data will be shown that transfection of the truncated protein exhibiting either one of the activities provoked increase of resistance. Since APE/Ref-1 expression level and intracellular localization is variable in different types of tumors and frequently found to be different in non-malignant compared to the corresponding malignant human tissue, the protein is thought to be a diagnostic and prognostic tumor marker. Because of its involvement in DNA repair and apoptosis-related signaling mechanisms, APE/Ref-1 is also being discussed as a novel target for tumor-therapeutic approaches.

p53 and regulation of DNA damage recognition during nucleotide excision repair

In response to a variety of types of DNA damage, the p53 tumor suppressor gene product is activated and regulates a number of downstream cellular processes such as cell cycle arrest, apoptosis and DNA repair. Recent discoveries concerning the regulation of DNA repair processes by p53, such as nucleotide excision repair (NER) and base excision repair (BER) have paved the way for studies to understand the mechanisms governing p53-dependent DNA repair. Although several theories have been proposed, accumulating evidence points to a transcriptional regulatory role for p53 in NER, mediating expression of the global genomic repair (GGR)-specific damage recognition genes, DDB2 and XPC. In BER, a more direct role for p53 has been proposed, potentially acting through protein-protein interactions with BER specific factors. These advances have greatly enhanced our understanding of the role of p53 in DNA repair and this review comprehensively summarizes current opinions on the mechanisms of p53-dependent DNA repair.

BRCA1 and p53: compensatory roles in DNA repair

The BRCA1 breast cancer susceptibility gene has been implicated in many cellular processes, yet its specific mechanism of tumor suppression remains unclear. BRCA1 plays a role in several DNA repair pathways including nucleotide excision repair (NER). Loss of the p53 tumor suppressor gene, a key regulator of NER, is an important and necessary event in the pathogenesis of BRCA1-mutated tumors. Here we discuss the role of BRCA1 and NER in breast cancer and the interactions of BRCA1 with p53 in breast tumorigenesis and suggest approaches for risk assessment and chemotherapeutic management of BRCA1-related breast cancer.

Cell cycle arrest and apoptosis provoked by UV radiation-induced DNA damage are transcriptionally highly divergent responses

DNA damage caused by UV radiation initiates cellular recovery mechanisms, which involve activation of DNA damage response pathways, cell cycle arrest and apoptosis. To assess cellular transcriptional responses to UVC-induced DNA damage we compared time course responses of human skin fibroblasts to low and high doses of UVC radiation known to induce a transient cellular replicative arrest or apoptosis, respectively. UVC radiation elicited >3-fold changes in 460 out of 12,000 transcripts and 89% of these represented downregulated transcripts. Only 5% of the regulated genes were common to both low and high doses of radiation. Cells inflicted with a low dose of UVC exhibited transcription profiles demonstrating transient regulation followed by recovery, whereas the responses were persistent after the high dose. A detailed clustering analysis and functional classification of the targets implied regulation of biologically divergent responses and suggested involvement of transcriptional and translational machinery, inflammatory, anti-proliferative and anti-angiogenic responses. The data support the notion that UVC radiation induces prominent, dose-dependent downregulation of transcription. However, the data strongly suggest that transcriptional repression is also target gene selective. Furthermore, the results demonstrate that dose-dependent induction of cell cycle arrest and apoptosis by UVC radiation are transcriptionally highly distinct responses.

The DDB2 nucleotide excision repair gene product p48 enhances global genomic repair in p53 deficient human fibroblasts

The tumor suppressor protein p53 functions in many cellular responses to UV-induced DNA damage, including activating the global nucleotide excision repair (NER) pathway. A potential mechanism for the effect on NER is through the ability of p53 to transcriptionally regulate genes that are directly involved in NER. DDB2 is one such gene that is regulated by p53 at both the basal and UV inducible levels. In order to further understand p53's role in NER, we transfected and selected clones that stably overexpress DDB2 in a human p53 deficient cell line. Global genomic repair (GGR) of cyclobutane pyrimidine dimers was significantly increased in the DDB2 expressing cells in comparison to controls, demonstrating that p53 wt protein itself is not directly required for efficient GGR. The protein product of DDB2, p48, is also post-translationally regulated by proteasomal degradation in response to UV irradiation. The regulation of p48 at both the transcriptional level by p53, and post-translationally by the proteasome suggests that p48 may be a rate limiting component of NER.

A novel regulation mechanism of DNA repair by damage-induced and RAD23-dependent stabilization of xeroderma pigmentosum group C protein

Primary DNA damage sensing in mammalian global genome nucleotide excision repair (GG-NER) is performed by the xeroderma pigmentosum group C (XPC)/HR23B protein complex. HR23B and HR23A are human homologs of the yeast ubiquitin-domain repair factor RAD23, the function of which is unknown. Knockout mice revealed that mHR23A and mHR23B have a fully redundant role in NER, and a partially redundant function in embryonic development. Inactivation of both genes causes embryonic lethality, but appeared still compatible with cellular viability. Analysis of mHR23A/B double-mutant cells showed that HR23 proteins function in NER by governing XPC stability via partial protection against proteasomal degradation. Interestingly, NER-type DNA damage further stabilizes XPC and thereby enhances repair. These findings resolve the primary function of RAD23 in repair and reveal a novel DNA-damage-dependent regulation mechanism of DNA repair in eukaryotes, which may be part of a more global damage-response circuitry.

UV wavelength-dependent regulation of transcription-coupled nucleotide excision repair in p53-deficient human cells

Nucleotide excision repair (NER) prevents skin cancer by eliminating highly genotoxic cyclobutane pyrimidine dimers (CPDs) induced in DNA by the UVB component of sunlight. NER consists of two distinct but overlapping subpathways, i.e., global NER, which removes CPD from the genome overall, and transcription-coupled NER (TCNER), which removes CPD uniquely from the transcribed strand of active genes. Previous investigations have clearly established that the p53 tumor suppressor plays a crucial role in the NER process. Here we used the ligation-mediated PCR technique to demonstrate, at nucleotide resolution along two chromosomal genes in human cells, that the requirement for functional p53 in TCNER, but not in global NER, depends on incident UV wavelength. Indeed, relative to an isogenic p53 wild-type counterpart, p53-deficient human lymphoblastoid strains were shown to remove CPD significantly less efficiently along both the transcribed and nontranscribed strands of the c-jun and hprt loci after exposure to polychromatic UVB (290-320 nm). However, in contrast, after irradiation with 254-nm UV, p53 deficiency engendered less efficient CPD repair only along the nontranscribed strands of these target genes. The revelation of this intriguing wavelength-dependent phenomenon reconciles an apparent conflict between previous studies which used either UVB or 254-nm UV to claim, respectively, that p53 is required for, or plays no role whatsoever in, TCNER of CPD. Furthermore, our finding highlights a major caveat in experimental photobiology by providing a prominent example where the extensively used "nonsolar" model mutagen 254-nm UV does not accurately replicate the effects of environmentally relevant UVB.

Loss of oncogenic H-ras-induced cell cycle arrest and p38 mitogen-activated protein kinase activation by disruption of Gadd45a

The activation of p53 is a guardian mechanism to protect primary cells from malignant transformation; however, the details of the activation of p53 by oncogenic stress are still incomplete. In this report we show that in Gadd45a(-/-) mouse embryo fibroblasts (MEF), overexpression of H-ras activates extracellular signal-regulated kinase (ERK) and c-Jun N-terminal kinase (JNK) but not p38 kinase, and this correlates with the loss of H-ras-induced cell cycle arrest (premature senescence). Inhibition of p38 mitogen-activated protein kinase (MAPK) activation correlated with the deregulation of p53 activation, and both a p38 MAPK chemical inhibitor and the expression of a dominant-negative p38alpha inhibited p53 activation in the presence of H-ras in wild-type MEF. p38, but not ERK or JNK, was found in a complex with Gadd45 proteins. The region of interaction was mapped to amino acids 71 to 96, and the central portion (amino acids 71 to 124) of Gadd45a was required for p38 MAPK activation in the presence of H-ras. Our results indicate that this Gadd45/p38 pathway plays an important role in preventing oncogene-induced growth at least in part by regulating the p53 tumor suppressor.

Subpathways of nucleotide excision repair and their regulation

Nucleotide excision repair provides an important cellular defense against a large variety of structurally unrelated DNA alterations. Most of these alterations, if unrepaired, may contribute to mutagenesis, oncogenesis, and developmental abnormalities, as well as cellular lethality. There are two subpathways of nucleotide excision repair; global genomic repair (GGR) and transcription coupled repair (TCR), that is selective for the transcribed DNA strand in expressed genes. Some of the proteins involved in the recognition of DNA damage (including RNA polymerase) are also responsive to natural variations in the secondary structural features of DNA. Gratuitous repair events in undamaged DNA might then contribute to genomic instability. However, damage recognition enzymes for GGR are normally maintained at very low levels unless the cells are genomically stressed. GGR is controlled through the SOS stress response in E. coli and through the activated p53 tumor suppressor in human cells. These inducible responses in human cells are important, as they have been shown to operate upon chemical carcinogen DNA damage at levels to which humans are environmentally exposed. Interestingly, most rodent tissues are deficient in the p53-dependent GGR pathway. Since rodents are used as surrogates for environmental cancer risk assessment, it is essential that we understand how they differ from humans with respect to DNA repair and oncogenic responses to environmental genotoxins. In the case of terminally differentiated mammalian cells, a new paradigm has appeared in which GGR is attenuated but both strands of expressed genes are repaired efficiently.